Gradual eigenvector ergodization in coupled Ginibre matrices

Abstract

Non-Hermitian random matrices provide a useful framework for understanding universal characteristics of dissipative quantum chaotic systems with loss or gain. We consider a model of two such system represented by two independent N× N complex Ginibre matrices interacting via a deterministic matrix c 1N, where c is the complex coupling parameter whose magnitude |c| controls the interaction strength. We characterize quantitatively how the eigenvectors of the whole system, initially localized in one of the individual subsystems for |c|=0, eventually spread over the full system with growing interaction strength. The resulting asymptotic formula describing such spread in the limit N ∞ is very explicit and provides a full picture of the gradual ergodization of eigenvectors as a function of the coupling parameter |c| in the whole transition regime. As a by-product of our method we also compute the mean eigenvalue density for our model at the origin of the spectral bulk z=0 in the fully ergodic regime, when the coupling is scaled with the matrix size as c=Nc. We find that as N ∞ the limiting density at the origin vanishes beyond the critical value |c|=1, signalling of a split of the density support in the complex plane into two disjoint domains.